Estimating Oceanic Primary Production Using ... - ACS Publications

Aug 24, 2015 - the water column.44 Nonspectral methods can overestimate PP by as much as ... (0 )(1. ) (1. ) tot. (2) where E(0. −. ) is the irradia...
0 downloads 0 Views 3MB Size
This is an open access article published under a Creative Commons Attribution (CC-BY) License, which permits unrestricted use, distribution and reproduction in any medium, provided the author and source are cited.

Article pubs.acs.org/est

Estimating Oceanic Primary Production Using Vertical Irradiance and Chlorophyll Profiles from Ocean Gliders in the North Atlantic Victoria S. Hemsley,*,†,‡ Timothy J. Smyth,§ Adrian P. Martin,‡ Eleanor Frajka-Williams,† Andrew F. Thompson,∥ Gillian Damerell,⊥ and Stuart C. Painter‡ ‡

National Oceanography Centre, Waterfront Campus, European Way, Southampton, SO14 3ZH, United Kingdom Ocean and Earth Science, National Oceanography Centre Southhampton, University of Southampton, SO14 3ZH, United Kingdom § Plymouth Marine Laboratory, Prospect Place, The Hoe, Plymouth, PL1 3DH, United Kingdom ∥ Environmental Science and Engineering, California Institute of Technology, Pasadena, California 91125, United States ⊥ School of Environmental Sciences, University of East Anglia, Norwich, NR4 7TJ, United Kingdom †

S Supporting Information *

ABSTRACT: An autonomous underwater vehicle (Seaglider) has been used to estimate marine primary production (PP) using a combination of irradiance and fluorescence vertical profiles. This method provides estimates for depth-resolved and temporally evolving PP on fine spatial scales in the absence of ship-based calibrations. We describe techniques to correct for known issues associated with long autonomous deployments such as sensor calibration drift and fluorescence quenching. Comparisons were made between the Seaglider, stable isotope (13C), and satellite estimates of PP. The Seaglider-based PP estimates were comparable to both satellite estimates and stable isotope measurements.

1. INTRODUCTION Primary production (PP) is the carbon fixed by plants through photosynthesis, the basis of almost all terrestrial and marine food webs. Marine phytoplankton fix 45−50 Gt C yr−1, approximately half of global PP.1,2 PP is critical for regulating the drawdown of atmospheric carbon dioxide3 and the air−sea exchange of radiatively important trace gases.4−6 In situ measurements of PP in the open ocean are sparse and avoid winter, making it difficult to resolve and separate spatial and temporal variability.1 Regular fixed-point sampling is difficult to extrapolate due to spatial variability. Satellites provide global estimates of oceanic PP over a range of spatial and temporal scales7−11 but, while satellitederived surface chlorophyll captures the variability in PP better than any other remotely sensed parameter,12 it relies on cloud free skies and only observes the top few meters, thereby omitting features such as subsurface chlorophyll maxima (SCM).13 As a result, PP estimates derived exclusively from satellite data typically underestimate spatial and temporal variability.1 Methods have been developed to accommodate SCM14 but are based on broad statistical relationships.15 Significant improvements in PP estimates from satellite surface chlorophyll fields are possible with simultaneous in situ chlorophyll and PAR (photosynthetically active radiation) profiles.12 Underwater gliders provide such data, improving the vertical and temporal resolution of observations.16,17 However, gliders use fluorescence as proxy for chlorophyll,19 and longduration missions may lack sufficient in situ calibration.18,20 We describe a method for estimating PP at high vertical and temporal resolution, using glider chlorophyll fluorescence and © 2015 American Chemical Society

irradiance profiles. Significantly, it uses irradiance to calibrate fluorescence and, therefore, needs no in situ samples for calibration. This method makes possible depth-resolved continuous estimates of PP over a full seasonal cycle, in all weather.

2. DATA SETS 2.1. Area of Study. Data were collected in the northeast Atlantic Ocean (48°41′ N, 16°11′ W) as part of the OSMOSIS (Ocean Surface Mixing, Ocean Submesoscale Interaction Study). This site is approximately 40 km southeast of the Porcupine Abyssal Plain sustained observatory (Figure 1).21,22 Currents in this area are generally weak,23,24 with mean dive averaged currents of 11 cm s−1. Patchy phytoplankton distributions with fine spatial scales (